| Autor: |
Grashchenkova, М. A., Tomina, A.-M. V., Burya, O. I., Krasnovyd, S. V., Konchits, A. A., Shanina, B. D. |
| Předmět: |
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| Zdroj: |
Nanosistemi, Nanomateriali, Nanotehnologii; 2023, Vol. 21 Issue 1, p139-161, 23p |
| Abstrakt: |
The paper considers the effect of low- (Uglen-9) and high-modulus (Ural- N-24/320) carbon fibres (CF) on the physical and technical characteristics of copolymer BSP-7/CF carbon plastics. All materials, namely, CF, BSP-7, and BSP-7/CF composites, demonstrate electron paramagnetic resonance (EPR) signals with different characteristics. The whole composite and its individual components’ properties, as well as the interaction of the matrix with fillers are studied. The shape of EPR spectrum of CF Ural is controlled by the conduction electrons in dependence on the sample and skinlayer thicknesses for microwaves. The EPR spectra of CF Ural and Uglen are isotropic showing that these are carbonized rather than graphitized fibres. CF Uglen is characterized by a significant specific surface area, which causes a strong (by ≅25 times) broadening of the EPR line due to the interaction of CF electron spins with spins of air oxygen. The technology for preparing the composites, which includes magnetic mixing of the components inevitably leads to the ferromagnetic (FM) and superparamagnetic absorption signals within both BSP-7/Ural and BSP-7/Uglen. The magnetic resonance characteristics of composites depend on porosity of the samples, nature and concentration of fillers and FM impurities. The study of the tribological properties of composites shows that addition of Uglen-9 and Ural-N-24/320 fibres leads to a significant positive effect: a decrease in the friction coefficient, linear wear intensity and heat release over the restored surface of the original polymer by 1.6–2.6, 18.9–81.3 and 1.65–2.6 times, respectively. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
| Externí odkaz: |
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